Electrically tunable planar liquid-crystal singlets for simultaneous spectrometry and imaging.

IF 19.4 1区 物理与天体物理 Q1 Physics and Astronomy
Zhou Zhou, Yiheng Zhang, Yingxin Xie, Tian Huang, Zile Li, Peng Chen, Yan-Qing Lu, Shaohua Yu, Shuang Zhang, Guoxing Zheng
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引用次数: 0

Abstract

Conventional hyperspectral cameras cascade lenses and spectrometers to acquire the spectral datacube, which forms the fundamental framework for hyperspectral imaging. However, this cascading framework involves tradeoffs among spectral and imaging performances when the system is driven toward miniaturization. Here, we propose a spectral singlet lens that unifies optical imaging and computational spectrometry functions, enabling the creation of minimalist, miniaturized and high-performance hyperspectral cameras. As a paradigm, we capitalize on planar liquid crystal optics to implement the proposed framework, with each liquid-crystal unit cell acting as both phase modulator and electrically tunable spectral filter. Experiments with various targets show that the resulting millimeter-scale hyperspectral camera exhibits both high spectral fidelity ( > 95%) and high spatial resolutions ( ~1.7 times the diffraction limit). The proposed "two-in-one" framework can resolve the conflicts between spectral and imaging resolutions, which paves a practical pathway for advancing hyperspectral imaging systems toward miniaturization and portable applications.

Abstract Image

用于同时进行光谱测量和成像的电可调平面液晶单晶。
传统的高光谱相机通过级联镜头和光谱仪来获取光谱数据立方体,这构成了高光谱成像的基本框架。然而,当系统向微型化发展时,这种级联框架需要在光谱和成像性能之间做出权衡。在这里,我们提出了一种光谱单透镜,它将光学成像和计算光谱学功能统一起来,从而能够制造出简约、微型和高性能的高光谱相机。作为一种范例,我们利用平面液晶光学技术来实现所提出的框架,每个液晶单元既是相位调制器,又是电可调光谱滤波器。对各种目标的实验表明,由此产生的毫米级高光谱照相机具有高光谱保真度(> 95%)和高空间分辨率(约为衍射极限的 1.7 倍)。所提出的 "二合一 "框架可以解决光谱分辨率和成像分辨率之间的矛盾,为推动高光谱成像系统走向微型化和便携式应用铺平了一条切实可行的道路。
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来源期刊
CiteScore
27.00
自引率
2.60%
发文量
331
审稿时长
20 weeks
期刊介绍: Light: Science & Applications is an open-access, fully peer-reviewed publication.It publishes high-quality optics and photonics research globally, covering fundamental research and important issues in engineering and applied sciences related to optics and photonics.
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